Atomic force microscopy of the EcoKI Type I DNA restriction enzyme bound to DNA shows enzyme dimerization and DNA looping

Atomic force microscopy (AFM) allows the study of single protein-DNA interactions such as those observed with the Type I Restriction-Modification systems. The mechanisms employed by these systems are complicated and understanding them has proved problematic. It has been known for years that these en...

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Published inNucleic acids research Vol. 37; no. 6; pp. 2053 - 2063
Main Authors Neaves, Kelly J, Cooper, Laurie P, White, John H, Carnally, Stewart M, Dryden, David T.F, Edwardson, J. Michael, Henderson, Robert M
Format Journal Article
LanguageEnglish
Published England Oxford University Press 01.04.2009
Oxford Publishing Limited (England)
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Summary:Atomic force microscopy (AFM) allows the study of single protein-DNA interactions such as those observed with the Type I Restriction-Modification systems. The mechanisms employed by these systems are complicated and understanding them has proved problematic. It has been known for years that these enzymes translocate DNA during the restriction reaction, but more recent AFM work suggested that the archetypal EcoKI protein went through an additional dimerization stage before the onset of translocation. The results presented here extend earlier findings confirming the dimerization. Dimerization is particularly common if the DNA molecule contains two EcoKI recognition sites. DNA loops with dimers at their apex form if the DNA is sufficiently long, and also form in the presence of ATPγS, a non-hydrolysable analogue of the ATP required for translocation, indicating that the looping is on the reaction pathway of the enzyme. Visualization of specific DNA loops in the protein-DNA constructs was achieved by improved sample preparation and analysis techniques. The reported dimerization and looping mechanism is unlikely to be exclusive to EcoKI, and offers greater insight into the detailed functioning of this and other higher order assemblies of proteins operating by bringing distant sites on DNA into close proximity via DNA looping.
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ISSN:0305-1048
1362-4962
DOI:10.1093/nar/gkp042